3D camera augmented Autonomous Mobile Robot for intralogistics purposes

János Simon; Alexandra Hegedűs; József Sárosi

doi:10.14232/analecta.2023.1.10-15

Authors

János Simon University of Szeged https://orcid.org/0000-0003-2870-5718
Alexandra Hegedűs Robotcenter Innovations Zrt.
József Sárosi University of Szeged https://orcid.org/0000-0002-6303-5011

DOI:

https://doi.org/10.14232/analecta.2023.1.10-15

Keywords:

AMR, mobile robotics, LiDAR sensor, 3D vision

Abstract

AMRs (Autonomous Mobile Robots) are driverless vehicles programmed to perform a variety of tasks and are often used to transport goods or materials. However, there can be several problems with the driving performance of this type of vehicle. Safety in the workplace is important everywhere, but there are some areas that are particularly exposed to safety risks. Limited visibility is the main cause of accidents at work. Yet, robots can map these dangerous areas with their sensors. We will present a mobile robotic sensor development that can be implemented to increase the security of robotic warehouses. Testing is necessary in order to check the quality of existing defects in safety elements before delivery and to carry out a risk assessment. Our goal was to add a safety element to the robot to prevent the most common problem, namely it is colliding with a forklift truck, hitting objects outside the sensor planes or hanging in. Based on our experience with robots over the years, this has been a big challenge, as we have had several such collisions. Therefore, we selected and installed a modern 3D camera system and tested its compliance with the safety requirements and the difference between the safety level of a robot without 3D sensor (Alpha) and a robot with 3D sensor (Beta), based on the knowledge of the installed camera.

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References

Vision - https://kinemetrix.com/expertise/3d-vision/, 2021

A. Kelly – Mobile Robotics matematics, models and methods, 2020

US survey - https://www.mordorintelligence.com, 2021

G. Brooker - Sensors for ranging and imaging, Institution of Engineering and Technology, 2015

Solutions for Mobile Platforms, 2021

Emanuelle Frontoni – Vision Based Mobile Robotics, 2006

US survey - https://www.mordorintelligence.com, 2021

A. Dahane, N. Eddine Berrec – Sensor Network, 2019

Robot vision - https://www.robots.com/articles/increase-product-quality-with-3d-vision, 2022

J. Borenstein, H. R. Everett – Navigating Mobile Robots, 1996

Seigwart – Autonomous Mobile Robotics, 2015

G. Klancar, A. Zdesar, S. Blazic, I. Skrjanc – Wheeled Mobile Robotics, Butterworth-Heinemann, 2017

J. Simon, M. Trojanova, A. Hošovský, J. Sarosi, “Neural Network Driven Automated Guided Vehicle Platform Development for Industry 4.0 Environment”, Tehnički vjesnik – Technical Gazette Vol.28, No.6, pp. 1936-1942, 2021. DOI: https://doi.org/10.17559/TV-20200727095821

3D vision - https://www.zivid.com/robot-mounted-3d-vision, 2021

Robot vision system - https://www.tm-robot.com/en/robot-vision-system/, 2021

Montgomery Anna – Mobile Robotics, 2015

Sick Visionary -T data sheet, 2021

D. Csík, Á. Odry, J. Sárosi, P. Sarcevic, Inertial sensor-based outdoor terrain classification for wheeled mobile robots, 2021 IEEE 19th International Symposium on Intelligent Systems and Informatics (SISY), Subotica, Serbia, September 16-18, 2021, pp. 159-164. DOI: https://dx.doi.org/10.1109/SISY52375.2021.9582504

Robot vision - https://www.robots.com/articles/increase-product-quality-with-3d-vision, 2022

Robot vision system - https://www.tm-robot.com/en/robot-vision-system/, 2021